KR101549589B1 - Power meter reading method with intelligent plc - Google Patents

Abstract

The present invention relates to a power measurement method using intelligent power line communication (PLC). The power measurement method is used to enable a master PLC modem and a slave PLC model which have a mutual master-slave relationship and exchange data using a PLC channel to take the channel status into consideration and determine whether to transmit data. The method includes: a first process in which the slave PLC modem transmits a channel estimation request command to the master PLC modem; a second process in which the master PLC modem transmits a channel estimation result response message to the slave PLC modem; a third process in which the slave PLC modem receives the channel estimation result response message to generate a tone map; a fourth step in which the slave PLC modem transmits the tone map to the master PLC modem through a pilot channel; a fifth step in which the master PLC modem transmits a data request signal to the slave PLC modem when the master PLC modem determines that a communication network is available for a communication operation without overload by analyzing the tone map; and a sixth step in which the slave PLC modem transmits the request data to the master PLC modem through a data channel.

Description

TECHNICAL FIELD [0001] The present invention relates to an intelligent PLC power meter reading method,

The present invention relates to an intelligent PLC power meter reading method, and more particularly, to a PLC meter power meter, which is capable of checking the state of a communication network according to information of a tone map generated through channel estimation between PLC modems, ), The communication between the PLC modem and the PLC modem is not good. By performing the meter reading process in accordance with the communication state, it is possible to prevent overload of the communication band to secure the communication reliability, And more particularly, to an intelligent PLC power meter reading method capable of securing the stability of the PLC power meter.

Power Line Communication (PLC), also called mains communication, power line transmission or power line telecommunications (PLT), broadband power line (BPL), power band or power line networking (PLN) It is used as a generic term for various systems that use power distribution wires for distribution.

Power line communications (PLC) carry voice and data by carrier by superimposing a standard 50Hz or 60Hz alternating current (AC) analog signal.

Power line communication (PLC) is advantageous in that it can communicate immediately with only a modem without having to install a separate communication network. However, since it is influenced by noise, communication failure is higher than other communication methods.

As a result, the conventional PLC modem uses the entire 1 to 30 MHz band as a communication channel, so that when the communication noise is large, the modem link is unstable and the meter reading data is missing, and the retry retry is performed, so that there is a problem in that stability and reliability of communication can not be guaranteed because it causes an overload to the communication band.

Korean Patent Publication No. 10-2010-0038080

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a system and method for transmitting a status signal, which can confirm the status of a communication network according to information of a tone map generated through channel estimation between PLC modems, By transmitting and receiving, when the signal between the PLC modem is not good, the meter reading process is performed in accordance with the communication state, thereby preventing overload of the communication band, thereby ensuring the reliability of communication and ensuring the stability of meter reading by performing appropriate meter reading Which is an intelligent PLC power meter.

According to an aspect of the present invention, there is provided an intelligent PLC power meter reading method, which includes a master PLC modem and a slave PLC modem that transmit and receive data using a PLC channel, Wherein the slave PLC modem transmits a 'channel estimation request' command to the master PLC modem; A second step of the master PLC modem transmitting a channel estimation result response message to the slave PLC modem; A third step of the slave PLC modem receiving the channel estimation result response message to generate a tone map; A fourth step of the slave PLC modem transmitting the tone map to the master PLC modem through a pilot channel; A fifth step of transmitting a data request signal to the slave PLC modem when the master PLC modem analyzes the received tone map and determines that the communication network can communicate without overloading; And a sixth step of the slave PLC modem transmitting data requested through the data channel to the master PLC modem.

The present invention has a technical effect of preventing overload of the communication band to secure reliability of communication and ensuring the stability of meter reading by performing appropriate meter reading.

1 shows a configuration of an intelligent PLC modem according to the present invention.
FIG. 2 is a diagram illustrating a channel estimation, a tone map generation, and a signal state transmission process using a pilot channel between a master PLC modem and a slave PLC modem according to the present invention.
FIG. 3 shows an embodiment in which a performance-period determining algorithm is applied during channel estimation in the process of FIG.
FIG. 4 is a view illustrating a result of generating a tone map on a monitor according to an exemplary embodiment of the present invention. Referring to FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 shows a configuration of an intelligent PLC modem according to the present invention.

1, an intelligent PLC modem 100 according to the present invention includes a power unit 110, a PLC coupler 120, a pilot channel processor 130, a storage unit 140, and a controller 150 .

The power supply unit 110 supplies power to the intelligent PLC modem 100 so that the intelligent PLC modem 100 is driven.

The PLC coupler 120 can perform power line communication by combining or separating a PLC signal and a power signal transmitted and received via a power line.

The pilot channel processing unit 130 may transmit and receive a status signal for confirming the state of the communication network between the PLC modems through a pilot channel according to information of a tone map generated through channel estimation between PLC modems It will help.

The storage unit 140 stores firmware necessary for operation of the modem and data processed by the modem. In this case, a storage medium for storing firmware includes a flash memory, a MRAM (Magnetic Non-volatile memory such as Random Access Memory (Random Access Memory), FeRAM (Ferroelectric RAM), PRAM (Phase Change RAM), ReRAM (Resistance RAM), PoRAM (Polymer RAM), NFGM (Nano Floating Gate Memory) A volatile memory such as SDRAM (Synchronous Dynamic RAM) or DRAM (Dynamic RAM) may be used.

The control unit 150 controls the power unit 110, the PLC coupler 120, the pilot channel processing unit 130, and the storage unit 140.

FIG. 2 is a diagram illustrating a channel estimation, a tone map generation, and a signal state transmission process using a pilot channel between a master PLC modem and a slave PLC modem according to the present invention.

2, the master PLC modem 100a and the slave PLC modem 100b have the master and slave master and slave relationship with each other and are identical to the intelligent PLC modem 100 of FIG. 1 .

First, the slave PLC modem 100b has a first process (a10) for transmitting a 'channel estimation request' command to the master PLC modem 100a.

Here, channel estimation generally refers to a process of calculating a channel interference value in a receiving apparatus. The channel interference includes, for example, Gaussian noise, sampling time offset, carrier frequency offset, multipath fading, Doppler effect, / Q imbalance.

Next, the master PLC modem 100a has a second process (a20) of transmitting a channel estimation result response message to the slave PLC modem 100b in response to the 'channel estimation request' command.

In this case, the channel estimation result response message includes, for example, a forward error correction index (FEC Ind), an AGC gain, a bit per symbol (BPS), and tone map information.

In other words, the forward error correction index (FEC Ind) indicates a value indicating a forward error correction related parameter to be used in data transmission from a source station to a destination station.

 The AGC gain is a value indicative of the degree of attenuation of the channel, and means a gain value of a reception AGC (Automatic Gain Control) for the received channel estimation request command frame.

 The number of bits per symbol (BPS) means the sum of the number of bits allocated to the entire tone within one symbol when generating the tone map.

The tone map indicates the number of bits allocated to each tone. For example, the number of bits that can be assigned to each tone is {0, 1, 2, 4, 6, 8, 10} In this case, each of them is represented by {0b0000, 0b0001, 0b0010, 0b0100, 0b0110, 0b1000, 0b1010}, that is, 4 bits per tone, and the tone positions transmitted through the tone map field are tones # 84 to # 1147, A method of assigning 0 bits to the tone is used.

Meanwhile, in the case of performing the first process (a10) and the second process (a20), the execution cycle determination algorithm (S100) can be applied.

Next, the slave PLC modem 100b generates a tone map for allocating the number of bits of each tone according to the frequency through the tone map information among the received channel estimation result response message. (a30).

In this case, as shown in FIG. 4, the tone map value per channel according to the frequency is 0 (communication network disabled state), 1 (communication network failure state), 2 (communication network good state), 4 State) as a vertical axis.

Next, the slave PLC modem 100b has a fourth process (a40) of transmitting a tone map to the master PLC modem 100a to confirm the communication state of each channel through the pilot channel.

Here, the pilot channel means a channel used for transmitting a tone map created so that the entire PLC channel corresponding to the frequency is not used for data transmission but a specific channel can be checked for the communication state of the communication network .

Next, the master PLC modem 100a checks the state of the communication network through the received tone map value. If it is determined that the communication network can communicate without overload, the master PLC modem 100a transmits a data request signal to the slave PLC modem 100b And a fifth step (a50).

Finally, the slave PLC modem 100b has a sixth step (a60) of transmitting the corresponding data to the master PLC modem 100a through the data channel in response to the received data request signal.

Here, the data channel means a data communication channel excluding a pilot channel for transmitting a signal status among all the PLC channels according to frequency.

FIG. 3 shows an embodiment in which a performance-period determining algorithm is applied during channel estimation in the process of FIG.

Referring to FIG. 3, the execution cycle determination algorithm S100 according to the present invention includes a cycle period between the master PLC modem 100a and the slave PLC modem 100b through the following steps S110 to S152 as follows: Channel estimation, and each step will be described below.

First, the slave PLC modem 100b has a first step (S110) of setting an initial value to a link check cycle upper limit value LC_MAXP as a variable link check cycle (LC_P) value.

In this case, although the link check cycle upper limit value LC_MAXP has a default value of 160 seconds, it is natural that the link check cycle upper limit value LC_MAXP can be changed according to the communication situation.

Next, a second step of waiting until the master PLC modem 100a performs a channel estimation operation in response to the 'channel estimation request' command and transmits the channel estimation result response message to the slave PLC modem 100b (S120).

Next, the slave PLC modem 100b has a third step (S130) of determining whether a channel estimation result response message is normally received from the master PLC modem 100a by performing a link check on each PLC channel.

If it is determined that the channel estimation result response message is not normally received (Fail) in the third step S130, a fourth step S141 of determining whether the current link check period LC_P value is the link check period lower limit value LC_MINP ).

In this case, although the lower limit value LC_MINP of the link check period has a default value of 10 seconds, it is of course possible to change it according to the communication situation.

If the link check period LC_P is the link check period lower limit value LC_MINP (YES) in the fourth step S141, the flow advances to the quick recovery process S200 to end the channel estimation operation.

If the link check period LC_P is not the link check period lower limit value LC_MINP in the fourth step S141 (NO), the fifth step S142 of reducing the current link check period LC_P by 1/2 is performed, And then proceeds to the second step S120 and the third step S130 in order.

In this case, if the channel estimation result response message is not normally received as a result of the third step S130, that is, if the channel estimation fails, the fourth step S141, the fifth step S142, The second step (S120), and the third step (S130).

That is, the period of the channel estimation is reduced by ½ of the initial setup time in order to increase the probability of success of the channel estimation by advancing the channel estimation at shorter intervals.

A sixth step of checking whether the current link check period LC_P is the link check period upper limit value LC_MAXP when it is determined that the channel estimation has succeeded at a certain moment after the channel estimation has failed in the third step S130 S151).

If it is determined in the sixth step S151 that the current link check period LC_P is the link check cycle upper limit value LC_MAXP (YES), the process returns to the second step S120.

If it is determined in the sixth step S151 that the current link check period LC_P is not the link check period upper limit value LC_MAXP (NO), the seventh step S152 (S130), the sixth step (S151), and the seventh step (S130) until it is determined that the channel estimation has failed in the third step (S130) S152), the second step (S120), and the third step (S130).

That is, the reason for performing the channel estimation by increasing the current link check period LC_P by two is that if the channel estimation is changed from a failed state to a successful state, the current link check period LC_P is relatively (For example, 20 seconds) so as to prevent the load on the communication network from being generated.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention.

100: Intelligent PLC modem
110:
120: PLC coupler
130: Pilot channel processor
140:
150:

Claims (4)

A method of intelligent PLC power meter reading method, wherein a master PLC modem and a slave PLC modem each having a mutual master relationship and transmitting and receiving data by using a PLC channel determine data transmission in consideration of channel conditions,
A first step of the slave PLC modem transmitting a channel estimation request command to the master PLC modem;
A second step of the master PLC modem transmitting a channel estimation result response message to the slave PLC modem;
A third step of the slave PLC modem receiving the channel estimation result response message to generate a tone map;
A fourth step of the slave PLC modem transmitting the tone map to the master PLC modem through a pilot channel;
A fifth step of transmitting a data request signal to the slave PLC modem when the master PLC modem analyzes the received tone map and determines that the communication network can communicate without overloading; And
And transmitting the data requested by the slave PLC modem through the data channel to the master PLC modem,
The tone map may further comprise:
(Communication network failure state), 2 (communication network good state), and 4 (communication network excellent state) according to the communication state of the PLC channel. Way.
delete 2. The method of claim 1, wherein the first step and the second step comprise:
Wherein the execution period determination algorithm is adapted to variably adjust a period for requesting channel estimation for the PLC channel according to a failure or success of channel estimation. 2. The method of claim 1, wherein the master PLC modem and the slave PLC modem,
A power supply unit for supplying electric power to operate the device;
A PLC coupler for performing power line communication by combining or separating a PLC signal and a power signal transmitted and received through a power line;
A pilot channel processing unit for processing the tone map so that the tone map can be transmitted and received through the pilot channel;
A storage unit for storing firmware required for operation of the modem and data processed by the modem; And
And a controller for controlling the power unit, the PLC coupler, the pilot channel processor, and the storage unit.

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